HOXB7 is an ERα cofactor in the activation of HER2 and multiple ER target genes leading to endocrine resistance

K Jin, S Park, WW Teo, P Korangath, SS Cho… - Cancer discovery, 2015 - AACR
Cancer discovery, 2015AACR
Why breast cancers become resistant to tamoxifen despite continued expression of the
estrogen receptor-α (ERα) and what factors are responsible for high HER2 expression in
these tumors remains an enigma. HOXB7 chromatin immunoprecipitation analysis followed
by validation showed that HOXB7 physically interacts with ERα, and that the HOXB7–ERα
complex enhances transcription of many ERα target genes, including HER2. Investigating
strategies for controlling HOXB7, our studies revealed that MYC, stabilized via …
Abstract
Why breast cancers become resistant to tamoxifen despite continued expression of the estrogen receptor-α (ERα) and what factors are responsible for high HER2 expression in these tumors remains an enigma. HOXB7 chromatin immunoprecipitation analysis followed by validation showed that HOXB7 physically interacts with ERα, and that the HOXB7–ERα complex enhances transcription of many ERα target genes, including HER2. Investigating strategies for controlling HOXB7, our studies revealed that MYC, stabilized via phosphorylation mediated by EGFR–HER2 signaling, inhibits transcription of miR-196a, a HOXB7 repressor. This leads to increased expression of HOXB7, ER target genes, and HER2. Repressing MYC using small-molecule inhibitors reverses these events and causes regression of breast cancer xenografts. The MYC–HOXB7–HER2 signaling pathway is eminently targetable in endocrine-resistant breast cancer.
Significance: HOXB7 acts as an ERα cofactor regulating a myriad of ER target genes, including HER2, in tamoxifen-resistant breast cancer. HOXB7 expression is controlled by MYC via transcriptional regulation of the HOXB7 repressor miR-196a; consequently, antagonists of MYC cause reversal of selective ER modulator resistance both in vitro and in vivo. Cancer Discov; 5(9); 944–59. ©2015 AACR.
See related commentary by Heideman et al., p. 909.
This article is highlighted in the In This Issue feature, p. 893
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